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IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 07 | July-2015, Available @ http://www.ijret.org 231
FINITE ELEMENT MODELING AND BENDING STRESS ANALYSIS
OF NON STANDARD SPUR GEAR
G Mallesh1, Avinash P
2, Melvin Kumar R
3, Sacchin G
4, Zayeem Khan
5
1Associate Professor, Dept. of Mechanical Engineering, SJCE, Mysuru-570 006, Karnataka, India
2Research Group, Dept. of Mechanical Engineering, SJCE, Mysuru-570 006, Karnataka, India
3Research Group, Dept. of Mechanical Engineering, SJCE, Mysuru-570 006, Karnataka, India
4Research Group, Dept. of Mechanical Engineering, SJCE, Mysuru-570 006, Karnataka, India
5Research Group, Dept. of Mechanical Engineering, SJCE, Mysuru-570 006, Karnataka, India
Abstract Gears are toothed wheels, transmitting power and motion from one shaft to another by means of successive engagement of teeth.
Having a higher degree of reliability, compactness, high velocity ratio and finally able to transmit motion at a very low velocity,
gears are gaining importance as the most efficient means for transmitting power. A gearing system is susceptible to problems such
as interference, backlash and undercut. The contact portions of tooth profiles that are not conjugate is called interference.
Furthermore due to interference and in the absence of undercut, the involute tip or face of the driven gear tends to dig out the
non-involute flank of the driver. The response of a spur gear and its wear is an engineering problem that has not been completely
overcome yet.
With the perspective of overcoming such defects and for increase the efficiency of gearing system, the use of a non-standard spur
gear i.e., an asymmetric spur gear having different pressure angles for drive and coast side of the tooth comes into picture. This
paper emphasis on the generation of an asymmetric spur gear tooth using modeling software and bending stress at the root of
Asymmetric spur gear tooth is estimated by finite element analysis using ANSYS software and results were compared with the
standard spur gear tooth.
Keywords: Asymmetric spur gear, Bending stress, Finite element method, Pressure angle
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1. INTRODUCTION
The most common means for transmitting power in the
modern mechanical engineering world is through the use of
gears. Their size vary from the minnows used in the watches
to the larger ones finding application in speed reducing
units. They function as vital elements of main and ancillary
mechanisms in machines. Toothed gears are used to change
the speed and power ratio as well as direction between input
and output. In ancient times, gears were produced using
wood with cylindrical pegs for cogs while animal fat grease
served as lubricant.
The metal gearing, it all started during the eighteenth
century industrial revolution in Britain, followed by the
early parts of nineteenth century during which science of
gear design and manufacturing was extensively developed.
Increasing demand for lighter automotive from customers,
the aerospace and automobile industries now rely upon
gears having increased strength, reliability and at the same
time having lighter weight. Hence, during the recent times,
the subject gear design is highly complicated and a
comprehensive one. For a designer of modern times, it is
important to remember that the main objective of a gear
drive is to transmit higher power with comparatively smaller
overall dimensions of the driving system, incurring
minimum cost at the production stage, runs reasonably free
of noise and vibration and requiring least maintenance.
Gears mainly suffer from fracture under bending stress,
surface failure under internal stress etc. arising out of
defects due to interference, backlash and undercut. In order
to overcome these difficulties an asymmetric serves as a
better choice over the conventional spur gear. An
asymmetric spur gear is one with low pressure angle profile
on drive side and high pressure angle profile on the coast
side of the teeth. This modification in standard spur gear
leads to the decrease the bending stress.
The purpose of the present work is to study the effect of
gear tooth geometry on gear tooth stress. Accuracy of the
results depends upon the development of geometrically
correct tooth profile. Many methods have been developed to
generate a symmetric spur gear tooth with standard cutters
for different cutter parameters. Hence, it is required to
develop gear profile using gear tooth parameters with the
help of computer aided modeling software. Apart from load
and tooth geometry the stresses in a gear tooth depends upon
various other factors. For the determination of bending
stress, a gear tooth is considered as a cantilever beam and
thus they are referred as static stresses. Further, the static
stresses are multiplied by a number of factors in order to
compensate each of the other influences. In the year 1892,
Wilfred Lewis made a path breaking discovery in the field
of gear technology by formulating the basic equation for the
estimation of bending stress in gear tooth.
IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
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Volume: 04 Issue: 07 | July-2015, Available @ http://www.ijret.org 232
So far, several methods have been developed to estimate the
tooth bending stress of symmetric involute gears. Two of
them are introduced by ISO 6336 and DIN 3990. These
standards are very much alike except for a few points and
each of them is based upon the following hypotheses.
The critical section of the tooth is defined by the point of
tangency with the root fillet of a line rotated 300 from tooth
centerline as shown in Figure.1.The compressive stress
produced by the radial component of the tooth load can be
neglected. Total tooth load acts at the tip of the tooth (only
in DIN 3990/Method C and ISO 6336/TC60 Method C).
Since there are no established method for asymmetric gear
tooth, the method given by Pedrero et al. [5] is used. The
adaptation is based on the following considerations:
The maximum tooth bending stress occurs at the point of
tangency with the root fillet of a line rotated 300 from the
tooth centerline on the drive side of asymmetric tooth as
shown in Figure.2.
Toothcentre line
30°
Critical section thickness
SF
rF
aL
F
Toothcentre line
Drive side
Coast side30°30°
Critiacl Section thickness
SF
rF
LaF
Fig-1: Symmetric tooth
model for bending stress
(DIN 3990)
Fig-2: Asymmetric tooth
model for bending stress
The stress that takes a very important part in tooth root crack
origination is maximum tensile stress 𝜎𝑡at the tooth root
region. The tensile stress 𝜎𝑡at the root of the tooth is given
by [11],
𝜎𝑡𝑚𝑎𝑥 =𝐹𝑡
𝑏𝑚𝐾𝑧𝐾𝜆𝐾𝑎 1.1
𝐾𝑧 = 3.56 + 4.59 1
𝑧1 + 1.740 1.2
𝐾𝜆 = exp 2.5 1
𝑧1 − 0.5
λ
m 1.3
𝐾𝑎 = 1.32 − 1.82 × 10−2𝜙 + 1.17 × 10−4𝜙2 1.4
𝜎𝑡𝑚𝑎𝑥 (MPa) maximum tensile stress, 𝐹𝑡 tangential tooth
load,𝑏 face width of the gear considered to be 10 times the
module 𝑚, module,𝐾𝑧 tooth number influence factor,𝐾𝜆 load
position influence factor,𝐾𝑎 pressure angle influence factor
and 𝑧1 number of teeth on pinion. The complex shape of the
gear teeth makes it difficult to calculate the stresses
accurately using the theory of elasticity. Based on the
previous work, empirical expressions obtained from Photo
elastic study [6] are reported to calculate the maximum
stresses in the gear tooth. Rapid growth in the field of
computer technology in the last few decades with respect to
speed of computation and storage capacity has made it
possible to compute the gear tooth stresses accurate enough
to satisfy the design considerations. Further, some more
empirical relations [7, 8, 9, and10] based on finite element
study and experimental analyses are also reported in the
literature. In the paper, 2D bending stress analyses was
carried out by the finite element method (FEM). The results
have been obtained by using the general purpose finite
element analysis software ANSYS 14.5.
2. LITERATURE REVIEW
Gears being the most critical components in power
transmission devices, the amount of available literature is
vast. Attempts made by several researchers to address issues
like bending and contact stress analysis, reliability and
fatigue life, noise reduction, vibration analysis etc. has
revealed that variations not only occur in the effects but also
in the basic assumptions made.
The basic asymmetric tooth geometry was developed by
Alexander L Kapelevich [11] in which the formulae and
equations for gear and generating rack parameters were
determined. In addition to this, the area of existence of
asymmetric gears was studied. The test conducted on
asymmetrical gears proved to be worthy as they show a
considerable reduction in weight, size and vibration levels
and increased loading capacity.
Using finite element method Gang Deng et al [12] worked
on determining the tooth stress and bending stress for
various combination of standard pressure angles (200/20
0,
200/25
0, 20
0/30
0 and 20
0/35
0). The results obtained clarified
that a larger standard pressure angle on the drive side of the
tooth makes the tooth root stress decrease remarkably and
bending stiffness increase without changing the load sharing
ratio.
Alexander L Kapelevich et al [13] were able to put forward
an alternative approach to conventional gear design called
direct gear design which described a substitute method for
the analysis and design of involute gears, to obtain a
satisfactory performance corresponding to a particular
application.
The studies conducted on the variation of bending stress and
contact ratio depending on pressure angle by Kadir Cavdar,
Fatih Karpat and Fatih C. Babalik [14] confirmed that, as
the pressure angle on the drive side increases, the bending
stress decreases and the bending load capacity increases.
IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 07 | July-2015, Available @ http://www.ijret.org 233
3. MODELLING OF ASYMMETRIC SPUR
GEAR TOOTH USING SOLID EDGE
Generate gear tooth model using different parameters given
in Table-1
Table-1: Gear tooth parameters
1 z1−No. of teeth on pinion 20
2 z2− No. of teeth on gear 30
3 x1− Profile shift on pinion 0.0
3 x2− Profile shift on Gear 0.0
4 𝛷1 − Pressure angle on coast
side
200
5 𝛷2 − Pressure angle on drive
side,
200- 35
0 by 1
0
increment
6 𝑀𝑛 − Module, mm 4
7 Radius of rack cutter fillet, mm 0.75
Calculate the required parameters like pitch circle diameter,
tooth thickness, addendum, clearance, dedendum and base
circle diameter using standard gear formulae.
Pitch circle diameter Dp= mz
Circular pitch Cp= πm
Tooth thickness T= 𝜋𝑚
2
Addendum = module
Addendum circle diameter = Dp+ 2 Addendum
Clearance = Cp
20
Dedendum = Addendum + clearance
Dedendum circle diameter = Dp – 2 dedendum
Fillet radius = Cp
8
Base circle diameter = Dpcosθ
Create pitch circle, addendum circle, dedendum circle and
base circle diameters using create circle command, draw a
line from the addendum circle to the base circle and divide
the lines into three equal segments 12, 23, 34 as shown in
the figure (a).Draw a line from point 2 such that it is tangent
to the base circle at point 5 then divide line 2-5 into four
equal divisions as shown in the figure (d) with ‘R’ as the
center ‘2R’ as the radius draw an arc between addendum
and dedendum circle which passes through the point 2.Draw
a fillet arc between dedendum circle and involute curve.
Taking tooth thickness arc from ‘2’ which cuts pitch circle
diameter at ‘M’ and repeat the procedure to get the involute
curve on the other side.
Using array command entire gear model has been developed
for symmetric and asymmetric spur gear tooth as shown in
figure.4
Fig-a Fig-b
Fig-c Fig-d
Fig-3: Procedure to create gear tooth profile
Full gear model of 200/20
0
pressure angle
Full gear model of 200/35
0
pressure angle
Fig-4: Full gear tooth model for different pressure angles on
drive side and coast side
Once the model has been created using solid edge software
the model then saved as *.iges file format, which can be
imported easily to the ANSYS environment to conduct
bending stress analysis.
4. FINITE ELEMENT ANALYSIS
Finite element method is the one which is primarily used to
determine the solution of a complex problem by replacing
the former by a simpler one. As the former is replaced, by
the latter in finding the solution, the method provides an
approximate solution instead of an exact solution. The
current mathematical tools are not sufficient to find exact
solution for most of the practical problems.
The realistic use of finite element method for solving the
problem involves preprocessing, analysis and post
processing. The preprocessing involves the preparation of
data such as nodal coordinates, element connectivity,
boundary conditions, loading and material properties. The
analysis stage involves stiffness generation, stiffness
modification and solution of the equations resulting in the
evaluation of nodal displacements and derived quantities
such as stresses. The post processing deals with presentation
of the results. A complete finite element analysis is a logical
interaction of the three stages.
IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 07 | July-2015, Available @ http://www.ijret.org 234
4.1 Load and Boundary Conditions
As a major part of present investigation, a series of finite
element analysis were carried out for different sets of
symmetric and asymmetric spur gears subjected to a load at
highest point of single tooth of contact (HPSTC) by
considering the tangential component of the load. Gears are
used to transmit power of 15kW at 1000 rpm. The gear tooth
is considered as a cantilever and is constrained at the rim
(A-B-C-D). All the elements have two degrees of freedom
while the elements at the rim are fixed. The meshed model
subjected to displacement and force boundary conditions is
as shown in Figure.5.
Fig-5: Gear tooth system considered for finite element
analysis with suitable boundary conditions
4.2 Solution Method for 2D Finite Element Method
In order to solve the system of equilibrium equations, Gauss
elimination method is used. The property of symmetry and
band form is utilized in the storage of global stiffness
matrix. The stress values was calculated for each element
using stress-strain relations. The strain-displacement matrix
for eight node quadrilateral element is a function of natural
coordinates 𝑠 and 𝑡 and vary within the element. Hence,
stresses evaluated at the Gauss points were found to be
accurate. The stress values at nodes are extrapolated from
values at Gauss points.
5. RESULTS AND DISCUSSIONS
Gear design is a multifaceted process due to the correlation
of various parameters. Gear parameter modification should
not violate the standards recommended for other parameters.
The effect of pressure angle modification on spur gear tooth
performance and its dependence on other parameters is
stated in the following sections.
5.1 Effect of Pressure Angle on Critical Section
Thickness
Critical section thickness plays an important gear tooth
parameter while evaluating bending stress. It is desirable to
have a broader critical section. Figure.6highlights the
variation of critical section thickness with the pressure
angle. As the pressure angle on the drive side increases, it is
seen that tooth thickness at the critical section increases,
enhancing the load carrying capacity. The results of critical
section thickness obtained are in good agreement with the
published results [14].
Fig-6: Variation of critical section thickness with pressure
angle
5.2 Effect of Pressure Angle on Tooth Thickness on
the Addendum Circle
The tooth thickness on the addendum circle depreciates with
increasing pressure angle on drive side. The studies carried
out on 6 mm module gear tooth segment depicted that an
increase in the pressure angle is limited to 400 as the
corresponding tooth thickness on the addendum circle
becomes 1.2 i.e., 0.2𝑀𝑛 [14].
Fig-7: Variation of tooth thickness on addendum circle with
pressure angle for 6 mm module
7.6
7.8
8
8.2
8.4
8.6
8.8
9
9.2
20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35
Tooth
thic
knes
s at
the
crit
ical
sec
tion,
mm
Pressure angle on drive side, deg
IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 07 | July-2015, Available @ http://www.ijret.org 235
Fig-8: Pointed tooth with 45
0 pressure angle on drive side4
mm module and zero profile shift.
The studies revealed that the pressure angle modification
influences the gear tooth profile whereas the module and
number of teeth bear no effect on gear tooth profile. These
conclusions come in handy in further assessment of gear
tooth stresses.
.
5.3 Effect of Pressure Angle on Gear Tooth Stresses
The stresses in a gear tooth depend primarily on the load and
the tooth geometry but there are several other phenomena
which must be taken into account. Stress estimation has
become important as it has been one of the primary reasons
of failure of gears. Studies conducted on gear tooth stress
have been discussed in the following sections.
5.3.1 Effect of Pressure Angle on Bending Stress
The bending stress is calculated considering the gear tooth
as a cantilever beam and is called as static stress which is
multiplied by a number of factors to compensate for each of
the other influences. Likewise, several methods have been
developed in bending stress estimation of symmetric gears.
However, in case of asymmetric gears, Tobe’s method [11]
has proved to be appropriate. Stress calculated using Tobe’s
method have been compared with 2D FEM results for 𝑀𝑛 =
4 mm;𝑋 = 0; 𝑧1 = 20 and 𝛽′ =1.2.
Table –2: Comparison of bending stresses for different
pressure angle
Pressure angle Bending stress, MPa
Theoretical FEA
20-20 57.05 56.87
20-21 56.31 56.01
20-22 55.53 54.16
20-23 54.72 53.87
20-24 53.86 52.79
20-25 52.95 53.23
20-26 51.98 51.45
20-27 51.08 51.50
20-28 50.12 49.92
20-29 49.09 49.27
20-30 47.99 49.03
20-31 46.81 46.53
20-32 45.54 44.27
20-33 44.17 44.05
20-34 42.64 42.06
20-35 41.39 42.35
It is observed that an increase in pressure angle on drive side
is accompanied by a substantial decrease in the bending
stress at the critical section. The comparison with Tobe’s
method showed a variation of ± 5% for 2D FEM analysis.
Thus the FEM analysis is considered suitable for stress
estimation and is adopted for further studies. Analysis of
symmetric (200/20
0) and asymmetric (20
0/35
0) spur gears
revealed a 25% stress reduction in asymmetric gears
keeping all other parameters same.
5.3.2 Stress Contours
From the stress contours, it can be inferred that an increase
in pressure angle along the drive side is coupled with the
decrease in the bending stress at the critical section for all
cases. The overall bending stress induced in case of 200/32
0
pressure angle combination is 45.54MPa. Further increase in
the pressure angle results in increase of overall bending
stress as the limiting value of tooth thickness on addendum
circle is reached at 200/32
0. Hence, pressure angle
modification study is restricted to 320 on the drive side [15].
A close observation of the above tabulations supports the
same.
Fig-9: Bending stress contours of 20
0/20
0 gear teeth
segment.
Fig-10: Bending stress contours of 20
0/25
0 gear teeth
segment.
IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 07 | July-2015, Available @ http://www.ijret.org 236
Fig-11: Bending stress contours of 20
0/30
0 gear teeth
segment.
Fig-12: Bending stress contours of 20
0/35
0 gear teeth
segment.
The variation between three teeth segment and full gear
body analysis is insignificant as established by the previous
works [16]. Hence, three teeth gear segment is considered
for analysis to study the effect of loading at HPSTC on
adjacent teeth stresses. Stress contours of 2D three teeth
gear segments analyses have been plotted for increasing
pressure angle on drive side (200-35
0) as shown in
Figures.9-12. The following parameters are considered for
the analysis; 𝑀𝑛 = 4 mm;𝑋 = 0; 𝑧1 = 20 ; 𝑧2 = 30 and
𝛽′ =1.2.
6. CONCLUSION
The assessment of pressure angle modification on drive side
leads to interesting conclusions. While the pressure angle
modification affects the gear tooth geometry, the
modification study is itself limited by gear parameters like
module, number of teeth, contact ratio and profile shift. It
has been observed that the pressure angle has insignificant
influence on the induced stress whereas the bending stress is
considerably reduced by increasing the pressure angle.
Following remarks can also be made regarding pressure
angle modification.
With the increase in the pressure angle, gears can be
operated with lesser number of teeth compared to
AGMA standards (𝑍𝑚𝑖𝑛 =2
𝑠𝑖𝑛 2 200 = 17.097)
since, undercutting is avoided.
The shape of the tooth becomes more pointed or
peaked and the tooth flank becomes more curved.
Vibration levels saw a significant reduction as a
result of low relative sliding velocity and moreover,
the wear is reduced.
The asymmetric tooth geometry allows for an
increase in load carrying capacity while reducing the
weight and dimensions for gears.
REFERENCES
[1]. G Mallesh, Dr VB Math, Prabodh Sai Dutt R Ashwij,
Rajendra Shanbhag, Effect of Tooth Profile Modification in
Asymmetric Spur Gear Tooth Bending Stress by Finite
Element Analysis (2009)
[2]. G Mallesh, Math VB Venkatesh, HJ Shankarmurthy, P
Prasad Shiva, K Aravinda, Parametric analysis of
Asymmetric Spur Gear Tooth (2009)
[3]. G Mallesh, Estimation of Critical Section and Bending
Stress Analysis for Asymmetric Spur Gear Tooth.
[4]. G Mallesh, Effect of Rim Thickness on Symmetric and
Asymmetric Spur Gear Tooth Bending Stress.
[5]. Pedrero, J.I., Artes M, Approximate equation for the
addendum modification factors for tooth gears with
balanced specific sliding, Mechanism and Machine
Theory, Vol. 31, pp. 925-93,1996
[6]. Thomas J. Dolan and Edward L. Broghamer, A photo
elastic study of stresses in gear tooth fillets, University Of
Illinois Engineering Experiment Station, Bulletin Series No.
335, 1942
[7]. ISO Standard 6336, Calculation of Load Capacity of
Spur and Helical Gears
[8]. Huseyin Filiz I, Eyercioglou O. Evaluation of gear tooth
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for Industry, Vol.117, pp. 232-219, 1995
[9]. R.Muthukumar and M.R.Raghavan, Estimation of gear
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[10]. Shuting Li , Finite element analyses for contact
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[11]. Kapelevich, A. L., Geometry and design of involute
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[13]. Alexander L. Kapelevich ,Direct gear design for
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[14]. Kadir Cavdar, Fatih Karpat, Fatih C. Babalik.,
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IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
_______________________________________________________________________________________
Volume: 04 Issue: 07 | July-2015, Available @ http://www.ijret.org 237
[15]. Fatih Karpat, Stephen Ekwaro, Probabilistic analysis
of MEMS asymmetric gear tooth, Journal of Mechanical
Design, Vol. 130, pp. (042306-1)-(042306-6), 2008
[16]. M. Celik, Comparison of three teeth and whole body
models in spur gear analysis, Mechanism and Machine
Theory, Vol.34, pp.1227-1235, 1999
BIOGRAPHIES
Dr. G Mallesh, Associate Professor,
Dept. Of ME, SJCE Mysuru-570006,
Karnataka, India
Avinash P, Research Group, Dept. Of
ME, SJCE Mysuru-570 006, Karnataka,
India
Melvin Kumar R, Research Group,
Dept. Of ME, SJCE Mysuru-570 006,
Karnataka, India
Sacchin G, Research Group, Dept. Of
ME, SJCE Mysuru-570 006, Karnataka,
India
Zayeem Khan, Research Group, Dept.
Of ME, SJCE Mysuru-570 006,
Karnataka, India